Model-based segmentation of an anatomical structure

ABSTRACT

A system and method is provided which obtains different medical images ( 210 ) showing an anatomical structure of a patient and having been acquired by different medical imaging modalities and/or different medical imaging protocols. The system is configured for fitting a first deformable model to the anatomical structure in the first medical image ( 220 A), fitting a second deformable model to the anatomical structure in the second medical image ( 220 B), mutually aligning the first fitted model and the second fitted model ( 230 ), and subsequently fusing the first fitted model and the second fitted model to obtain a fused model ( 240 ) by augmenting the first fitted model with a part of the second fitted model which is missing in the first fitted model; or adjusting or replacing a part of the first fitted model based on a corresponding part of the second fitted model having obtained a better fit. The fused model represents a multimodal/multi-protocol segmentation of the anatomical structure, and provides a user with a more comprehensive understanding of the anatomical structure than known models.

FIELD OF THE INVENTION

The invention relates to a system and method for fitting a deformablemodel to an anatomical structure in a medical image to obtain asegmentation of the anatomical structure. The invention further relatesto a workstation and imaging apparatus comprising the system, and to acomputer program product comprising instructions for causing a processorsystem to perform the method.

BACKGROUND OF THE INVENTION

Robust automatic segmentation of various anatomical structures in amedical image is a key enabler in improving clinical workflows. Here,the term segmentation refers to the identification of the anatomicalstructure in the medical image by, e.g., delineation of the boundariesof the anatomical structure, or by labeling of the voxels enclosed bythe boundaries. Once such segmentation has been performed, it ispossible to extract clinical parameters such as, in case of a cardiacstructure, ventricular mass, ejection fraction and wall thickness.Consequently, automatic segmentation can significantly reduce thescan-to-diagnosis time, and thus help clinicians in establishing moreefficient patient management.

It is known to segment an anatomical structure in a medical image usinga deformable model. Such type of segmentation is also referred to asmodel-based segmentation. The deformable model may be defined by modeldata. In particular, the model data may define a geometry of theanatomical structure, e.g., in the form of a multi-compartmental mesh oftriangles. Inter-patient and inter-phase shape variability may beefficiently accounted for by assigning an affine transformation to eachpart of such a deformable model. Affine transformations covertranslation, rotation, scaling along different coordinate axes andshearing. Moreover, mesh regularity may be maintained by interpolationof the affine transformations at the transitions between different partsof the deformable model. It is noted that such deformable models arealso referred to as mean shape models.

The fitting or applying of a deformable model to the image data of themedical image, also referred to as mesh adaptation, may involveoptimizing an energy function which may be based on an external energyterm which helps to adapt the deformable model to the image data and aninternal energy term which maintains a rigidness of the deformablemodel. It is noted that such an external energy term might make use ofboundary detection functions that were trained during a so-termedsimulated search, and may model different image characteristics inherentto different medical imaging modalities and/or protocols.

Deformable models of the above described type are known per se, as aremethods of applying such models to an anatomical structure in a medicalimage.

For example, a publication titled “Automatic Model-based Segmentation ofthe Heart in CT Images” by O. Ecabert et al., IEEE Transactions onMedical Imaging 2008, 27(9), pp. 1189-1201, describes a model-basedapproach for the automatic segmentation of the heart (four chambers,myocardium, and great vessels) from three-dimensional (3D) ComputedTomography (CT) images. Here, model adaptation is performedprogressively increasing the degrees-of-freedom of the alloweddeformations to improve convergence as well as segmentation accuracy.The heart is first localized in the image using a 3D implementation ofthe generalized Hough transform. Pose misalignment is corrected bymatching the model to the image making use of a global similaritytransformation. The complex initialization of the multi-compartment meshis then addressed by assigning an affine transformation to eachanatomical region of the model. Finally, a deformable adaptation isperformed to accurately match the boundaries of the patient's anatomy.

SUMMARY OF THE INVENTION

A problem of anatomical modeling is that a segmentation of theanatomical structure, as obtained by the fitting of a deformable model,provides a user with an insufficiently comprehensive understanding ofthe anatomical structure.

It would be advantageous to obtain a segmentation of the anatomicalstructure which provides a user with a more comprehensive understandingof the anatomical structure.

To better address this concern, a first aspect of the invention providesa system for fitting a deformable model to an anatomical structure in amedical image to obtain a segmentation of the anatomical structure,comprising:

an image interface for obtaining a first medical image of a patient anda second medical image of the patient, both medical images showing theanatomical structure and having been acquired by different medicalimaging modalities or different medical imaging protocols, therebyestablishing a different visual representation of the anatomicalstructure in both medical images;

a processing subsystem configured for:

i) fitting a first deformable model to the anatomical structure in thefirst medical image, thereby obtaining a first fitted model;ii) fitting a second deformable model to the anatomical structure in thesecond medical image, thereby obtaining a second fitted model; whereinthe second deformable model differs from the first deformable model foraccommodating said different visual representation of the anatomicalstructure in both medical images;iii) mutually aligning the first fitted model and the second fittedmodel, andiv) after said mutual alignment, fusing the first fitted model and thesecond fitted model to obtain a fused model.

A further aspect of the invention provides a workstation or imagingapparatus comprising the system.

A further aspect of the invention provides a method for fitting adeformable model to an anatomical structure in a medical image to obtaina segmentation of the anatomical structure, comprising:

obtaining a first medical image of a patient and a second medical imageof the patient, both medical images showing the anatomical structure andhaving been acquired by different medical imaging modalities ordifferent medical imaging protocols, thereby establishing a differentvisual representation of the anatomical structure in both medicalimages;

fitting a first deformable model to the anatomical structure in thefirst medical image, thereby obtaining a first fitted model;

fitting a second deformable model to the anatomical structure in thesecond medical image, thereby obtaining a second fitted model; whereinthe second deformable model differs from the first deformable model foraccommodating said different visual representation of the anatomicalstructure in both medical images;

mutually aligning the first fitted model and the second fitted model,and

after said mutual alignment, fusing the first fitted model and thesecond fitted model to obtain a fused model.

The above measures involve obtaining at least two medical images of apatient which each show an anatomical structure such as an organ, partof an organ, etc. The anatomical structure is represented by the imagedata of each medical image. The at least two medical images, henceforthalso referred to as ‘both’ medical images, are obtained from differentmedical imaging modalities and/or different medical imaging protocols.Here, the term ‘medical imaging modality’ refers to an type of imaging,which includes, but is not limited to, standard (rotational) X-rayImaging, Computed Tomography (CT), Magnetic Resonance (MR), Ultrasound(US), Positron Emission Tomography (PET), Single Photon EmissionComputed Tomography (SPECT), and Nuclear Medicine (NM). Another term formedical imaging modality is medical acquisition modality. Medicalimaging employing different medical imaging protocols is also referredto as multi-protocol or multi-parametric imaging. An example of suchmulti-protocol imaging is the use of different contrast agents and/ortracers to highlight specific anatomical structures in the acquiredmedical images.

Accordingly, the first medical image may be a CT image and the secondmedical image may be an MR image. Another example is that the firstmedical image may be a static CT image and the second medical image maybe a multi-phase CT image. Due to the use of different imagingmodalities and/or imaging protocols, the anatomical structure isdifferently represented in both medical images. For example, anatomicalinformation may be well visible in one medical image but less or notvisible in the other medical image.

Different deformable models are provided for fitting the anatomicalstructure in the respective medical images. The deformable models differin that they take into account that the anatomical structure has adifferent visual representation in each respective medical image. Suchdifferences may concern, e.g., different mesh topologies, differentlydefined energy terms, etc. As such, each deformable model may take intoaccount the visual properties of the anatomical structure when acquiredby the respective imaging modality and/or imaging protocol. For example,the first deformable model may have been generated for fitting thevisual representation of a heart in a CT image whereas the seconddeformable model may have been generated for fitting the heart in a MRimage.

The deformable models are applied to the anatomical structure in therespective medical images. As a result, a first fitted model is obtainedsegmenting the anatomical structure in the first medical image and asecond fitted model is obtained segmenting the anatomical structure inthe second medical image. It is noted that due to the difference indeformable model and the difference in visual representation of theanatomical structure in both medical images, both fitted modelstypically differ in shape.

The fitted models are mutually aligned. As a result of the mutualalignment, a commonly positioned part of both fitted models correspondsto a same part of the anatomical structure. It is noted that suchalignment may be based on a matching of commonalities between the fittedmodels, i.e., using a model-based registration. Alternatively oradditionally, the alignment may be based on a matching of commonalitiesbetween the first medical image and the second medical image, i.e.,using an image-based registration.

After being mutually aligned, the fitted models are fused. As a result,a fused model is obtained which represents a result of the fusion of thefitted models. Here, the term ‘fusion’ refers to information from thefitted models, in particular shape information, being combined so as toobtain the fused model. A non-limiting example may be that differentparts of the fused model may originate from either the first fittedmodel or the second fitted model.

The inventors have recognized that, nowadays, many clinical decisionsare not based on a single modality or protocol anymore. Instead, theimage data of different imaging modalities and/or imaging protocols isstudied to receive a more comprehensive understanding of an anatomicalstructure, such as its morphology and function. By fusing the deformablemodels after being fitted to medical images obtained from differentimaging modalities and/or imaging protocols, a clinician who would liketo obtain a comprehensive understanding of an anatomical structure doesnot need to refer anymore to the segmentation results of differentmedical workstations. Rather, the fused model represents a multi-modaland/or multi-protocol segmentation of the anatomical structure.Advantageously, it is not needed to mentally fuse separately obtainedmodeling results into a single model.

Advantageously, it is not needed to perform measurements, interact withthe model, etc., for each modality separately. Rather, such actions maybe applied to the (single) fused model.

U.S. 2012/0230568 A1 describes a model-based fusion of multi-modalvolumetric images. However, this differs from the present invention asU.S. 2012/0230568 A1 uses differences between models estimated frommulti-modal images to obtain a transformation for enabling the differentimages to be fused into a single image.

Optionally, the processing subsystem is configured for fusing the firstfitted model and the second fitted model by:

i) augmenting the first fitted model with a part of the second fittedmodel which is missing in the first fitted model; orii) adjusting or replacing a part of the first fitted model based on acorresponding part of the second fitted model having obtained a betterfit.

By augmenting or replacing part of the first fitted model with a part ofthe second fitted model, a hybrid fused model is obtained, i.e.,incorporating parts of different fitted models. By adjusting part of thefirst fitted model based on a corresponding part of the second fittedmodel, model information of a different fitted model is used to modifythe first fitted model, thereby obtaining the fused model. These optionsare well suited for obtaining a fused model which represents amulti-modal segmentation of the anatomical structure. It is noted thatin order to evaluate such a better fit, the processing subsystem maymake use of a goodness-of-fit function or similar type of qualityevaluation function.

Optionally, the system further comprises a visualization subsystem forvisualizing the fused model. The visualization subsystem allows thefused model to be visualized to a user such as a clinician. For example,the visualization subsystem may generate display data which, whendisplayed on a display, displays the fused model. It is noted that thedisplay may, but does not need to, be part of the visualizationsubsystem.

Optionally, the visualization subsystem is configured for visualizingthe fused model by overlaying the fused model over a displayed image,the displayed image being at least one of the group of: the firstmedical image, the second medical image, and a fused medical imageobtained by an image fusion of the first medical image and the secondmedical image. By overlaying the fused model over the displayed image,the user is enabled to obtain a more comprehensive understanding of theanatomical structure. In this respect, it is noted that the image fusionof the first medical image and the second medical image may be performedbased on segmentation provided by the fused model.

Optionally, the visualization subsystem is configured for processing thedisplayed image based on the fused model. Since the fused modelrepresents a multi-modal and/or multi-protocol segmentation of theanatomical structure which is deemed to better model the anatomicalstructure than either of the fitted models individually, said fusedmodel may be advantageously used in further processing the displayedimage. For example, an image enhancement may be applied based on thesegmentation provided by the fused model. Another example is that thefused model may be used to better segment the anatomical structure inthe displayed image.

Optionally, the visualization subsystem is configured for processing thedisplayed image by cropping the displayed image based on anatomicalinformation derived from the fused model. By cropping the displayedimage based on such anatomical information, unnecessary image data canbe omitted from display. Advantageously, the cognitive burden ofinterpreting the displayed image is reduced.

Optionally, the processing subsystem is configured for determining adiscrepancy between the first fitted model and the second fitted model,wherein the visualization subsystem is configured for visualizing thediscrepancy in visual relation with the fused model. Such a discrepancymay be of clinical relevance and is therefore visualized. By visualizingthe discrepancy in visual relation with the fused model, the cognitiveburden of interpreting the discrepancy is reduced.

Optionally, the visualization subsystem is configured for visualizingthe discrepancy by visually coding a display of the fused model. Here,the term ‘visually coding’ refers to adapting the display of the fusedmodel to visualize the discrepancy. For example, a color coding of thefused model may be used to visually indicate the location or themagnitude of the discrepancy.

Optionally, the first medical image is constituted by a time-series ofimages, wherein the first deformable model is arranged for modeling achange in the anatomical structure over the time-series of images, andwherein the visualization subsystem is configured for visuallyrepresenting the change in the visualizing of the fused model. Forexample, the first medical image may be a four-dimensional (4D) imageconsisting of a series of three-dimensional (3D) images acquired atdifferent times, e.g., at different cardiac phases. By determining thechange in the anatomical structure across the series and visualizingsaid change in the fused model, the user can conveniently, i.e., withlittle cognitive burden, obtain a comprehensive overview of theanatomical structure together with the change in the anatomicalstructure.

Optionally, the visualization subsystem is configured for animating thefused model to visually represent the change. Such animating of thefused model is well suited for visualizing the change in the anatomicalstructure.

Optionally, the system further comprises a user interaction subsystemfor enabling a user to interact with the fused model. For example, theuser may use a pointer to select, drag or otherwise interact with (apart of) the fused model.

Optionally, the user interaction subsystem is configured for carryingout an action with respect to a part of, one of the group of: the firstmedical image, the second medical image, the first fitted model and thesecond fitted model, based on the user interacting with a correspondingpart of the fused model. Hence, an action is carried out with respect toa part of either medical image, i.e., with respect to a locationtherein, or a part of either fitted model, based on the user interactingwith a corresponding part of the fused model. For example, the user mayadd an annotation to a selected part of the fused model which causes theannotation to be added to a location the first medical image whichcorresponds, i.e., represents similar content, to the part of the fusedmodel.

In summary, a system is provided which obtains different medical imagesshowing an anatomical structure of a patient and having been acquired bydifferent medical imaging modalities and/or different medical imagingprotocols. The system is configured for fitting a first deformable modelto the anatomical structure in the first medical image, fitting a seconddeformable model to the anatomical structure in the second medicalimage, mutually aligning the first fitted model and the second fittedmodel, and subsequently fusing the first fitted model and the secondfitted model to obtain a fused model. The fused model represents amulti-modal/multi-protocol segmentation of the anatomical structure, andprovides a user with a more comprehensive understanding of theanatomical structure than known models. It will be appreciated by thoseskilled in the art that two or more of the above-mentioned embodiments,implementations, and/or aspects of the invention may be combined in anyway deemed useful.

Modifications and variations of the system and/or the computer programproduct, which correspond to the described modifications and variationsof the method, can be carried out by a person skilled in the art on thebasis of the present description.

A person skilled in the art will appreciate that the invention may beapplied to multi-dimensional image data, e.g. to two-dimensional (2D),three-dimensional (3D) or four-dimensional (4D) images, acquired byvarious acquisition modalities such as, but not limited to, standardX-ray Imaging, Computed Tomography (CT), Magnetic Resonance Imaging(MRI), Ultrasound (US), Positron Emission Tomography (PET), SinglePhoton Emission Computed Tomography (SPECT), and Nuclear Medicine (NM).

The invention is defined in the independent claims. Advantageousembodiments are defined in the dependent claims.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other aspects of the invention are apparent from and will beelucidated with reference to the embodiments described hereinafter. Inthe drawings,

FIG. 1 shows a system for obtaining a fused model by fitting differentdeformable models to different medical images and subsequently fusingthe fitted models, with the system further comprising a visualizationsubsystem for visualizing the fused model and a user interactionsubsystem for enabling a user to interact with the fused model.

FIG. 2 shows a method for obtaining the fused model;

FIG. 3 shows a computer program product comprising instructions forcausing a processor system to perform the method;

FIG. 4 shows a flow diagram of an embodiment of the present invention;and

FIG. 5A shows an example of a first fitted model in the form of ahigh-resolution full heart model with a flat annular plane dedicated tostatic CT;

FIG. 5B shows an example of a second fitted model in the form ofmedium-resolution heart model with dynamic aortic valve model dedicatedto 4D TEE; and

FIG. 5C shows a fused model in the form of a high resolution full heartmodel with dynamic aortic valve model, obtained by fusing the firstfitted model and the second fitted model.

DETAILED DESCRIPTION OF EMBODIMENTS

FIG. 1 shows a system 100 for fitting a deformable model to ananatomical structure in a medical image to obtain a segmentation of theanatomical structure. The system 100 comprises an image interface 120for obtaining a first medical image of a patient and a second medicalimage of the patient. Both medical images show the anatomical structureand having been acquired by different medical imaging modalities ormedical imaging protocols, thereby establishing a different visualrepresentation of the anatomical structure in both medical images. FIG.1 shows the image interface 120 obtaining the medical images in the formof image data 042 from an external database 040, such as a PictureArchiving and Communication System (PACS). As such, the image interface120 may be constituted by a so-termed DICOM interface. However, theimage interface 120 may also take any other suitable form, such as amemory or storage interface, a network interface, etc.

The system 100 further comprises a processing subsystem 140. Theprocessing subsystem 140 is configured for, during operation of thesystem 100, fitting a first deformable model to the anatomical structurein the first medical image, thereby obtaining a first fitted model, andfitting a second deformable model to the anatomical structure in thesecond medical image, thereby obtaining a second fitted model. Suchdeformable models may be available to the processing subsystem 140 inthe form of model data, defining, e.g., a mesh topology, one or moreenergy terms for fitting the mesh to the image data, etc. The processingsubsystem 140 is further arranged for mutually aligning the first fittedmodel and the second fitted model, and after said mutual alignment,fusing the first fitted model and the second fitted model to obtain afused model. The processing subsystem 140 may then make the fused modelavailable, e.g., by outputting model data 142 defining the fused model.

In accordance with an optional aspect of the present invention, FIG. 1shows the system 100 further comprising a visualization subsystem 160for visualizing the fused model. For that purpose, the visualizationsubsystem 160 is shown to receive the model data 142 from the processingsubsystem 140, and to provide display data 162 to a display 010. Thevisualization subsystem 160 may visualize the fused model by overlayingthe fused model over a displayed image. The displayed image mayconstituted by, e.g., the first medical image, the second medical image,or a fused medical image obtained by an image fusion of the firstmedical image and the second medical image. For that purpose, thevisualization subsystem 160 may receive image data 042 from the imageinterface 120.

In accordance with a further optional aspect of the present invention,FIG. 1 shows the system 100 further comprising a user interactionsubsystem 180 for enabling a user to interact with the fused model. Forexample, a user may operate a user input device 020 such as a computermouse, keyboard, touch screen, etc., thereby providing user input 022 tothe system 100 representing user commands 182. Upon receiving such usercommands 182, the processing subsystem 140 may carry out an action withrespect to a part of the first medical image, the second medical imageand/or the first fitted model and the second fitted model, based on theuser interacting with a corresponding part of the fused model.

It is noted that the operation of the system 100, including variousoptional aspects thereof, will be further described with reference toFIGS. 4 and 5A, 5B and 5C.

FIG. 2 shows a method 200 for fitting a deformable model to ananatomical structure in a medical image to obtain a segmentation of theanatomical structure. The method 200 comprises, in a step titled“OBTAINING MEDICAL IMAGES”, obtaining 210 a first medical image of apatient and a second medical image of the patient, both medical imagesshowing the anatomical structure and having been acquired by differentmedical imaging modalities or medical imaging protocols, therebyestablishing a different visual representation of the anatomicalstructure in both medical images. The method 200 further comprises, in astep titled “FITTING FIRST DEFORMABLE MODEL TO FIRST MEDICAL IMAGE”fitting 220A a first deformable model to the anatomical structure in thefirst medical image, thereby obtaining a first fitted model. The method200 further comprises, in a step titled “FITTING SECOND DEFORMABLE MODELTO SECOND MEDICAL IMAGE”, fitting 220B a second deformable model to theanatomical structure in the second medical image, thereby obtaining asecond fitted model; wherein the second deformable model differs fromthe first deformable model for accommodating said different visualrepresentation of the anatomical structure in both medical images. Themethod 200 further comprises, in a step titled “MUTUALLY ALIGNING THEFITTED MODELS”, mutually 230 aligning the first fitted model and thesecond fitted model. The method 200 further comprises, in a step titled“FUSING THE FITTED MODELS”, after said mutual alignment, fusing 240 thefirst fitted model and the second fitted model to obtain a fused model.

It is noted that the above steps may be performed in any suitable order.For example, the steps of fitting 220A the first deformable model andfitting 220B the second deformable model may be performed simultaneouslyor sequentially. Moreover, the step of mutually 230 aligning the firstfitted model and the second fitted model may be performed by aligningthe medical images themselves, which may be performed before, during, orafter fitting 220A the first deformable model and fitting 220B thesecond deformable model.

FIG. 3 shows a computer program product comprising instructions forcausing a processor system to perform the method of FIG. 2, i.e.,comprising a computer program. The computer program may be comprised ina non-transitory manner on a computer readable medium 260, e.g., as aseries 250 of machine readable physical marks and/or as a series ofelements having different electrical, e.g., magnetic, or opticalproperties or values.

The operation of the system of FIG. 1 and the method of FIG. 2,including various optional aspects thereof, may be explained in moredetail as follows.

FIG. 4 shows a flow diagram of an embodiment of the present invention.The embodiment illustrates two cardiac clinical application scenarios inwhich the invention may be advantageously applied, namely the viewingand analysis of an 2D/3D/4D echocardiography dataset in relation to a 3DMulti-Slice CT (MSCT) dataset. Here, the term ‘dataset’ refers to imagedata representing at least one medical image. Consequently, fitting adeformable model to a dataset refers to the deformable model beingfitted to at least one medical image of the dataset. It is noted that incases where the dataset represents a time-series or other series ofmedical images, e.g., showing the heart across different cardiac phases,fitting a deformable model to the dataset may comprise fitting adeformable model to each medical image, thereby obtaining a segmentationof the heart in each of the different cardiac phases. This may be thecase if, e.g., the echocardiography dataset is a 4D dataset.

Initially, in a step 310A, a reference dataset is acquired, e.g., from acardiac MSCT angiography. In a further step 320A, the reference datasetmay be segmented using a dedicated CT model, i.e., by fitting the CTmodel to the reference dataset. As a result, a personalized CT-specificmodel may be obtained, i.e., a first fitted model represented by a mesh.In a step 310B, a further dataset of the same patient may be acquired,e.g., from a Transesophageal Echocardiogram (TEE) study consisting of2D, 3D and 4D image data or a rotational C-arm CT with a selectivecontrast agent injection. In a further step 320B, the further datasetmay be segmented using one or more dedicated model(s), resulting in atleast one more fitted models, i.e., at least a second fitted model. Thefirst fitted model and the second fitted model may then both be fused ina step 340 to obtain a fused model.

However, to first mutually align the different fitted models, a numberof processing steps may be performed, commonly denoted as step 325A forthe first fitted model and step 325B for the second fitted model. Thesesteps may comprise:

1. Roughly aligning the first fitted model and the second fitted model.This constitutes a registration problem, and more specifically amesh-to-mesh or segmentation-based registration problem. To solve such aproblem, Iterative Closest Point (ICP)-based algorithms may be used.Such algorithms may be adapted to take into account differences, e.g.,in mesh topology, between both fitted models. For example, the firstfitted model may comprise a dynamic heart valve structure which is notpart of the second fitted model. For that purpose, an anatomy-specific(binary) weighting scheme may be employed.2. Refining the registration based on matching of pre-defined anchorstructures, such as, e.g., the aortic root or the mitral valve annulus,to each other. In the earlier mentioned case of CT/TEE mitral valvefusion, such refinement may be as follows. Since CT is geometricallymore accurate and is able to image a full heart, the deformable modelfitting this dataset may be used as a geometrical reference. ATEE/Doppler of the mitral valve shows only parts of the Left Atria (LA)and the Left Ventricle (LV) but the complete mitral valve in hightemporal resolution. A segmentation of this dataset may result in a setof meshes that represent the motion of the valve leaflets together witha crude segmentation of the surrounding structure. Both datasets jointlyshow the mitral valve annulus which may therefore be used as anchorstructures. A (elastic) deformation may be applied to the TEE meshes toconform to the geometry of the reference CT/MR mesh. The same(inherited) deformation may be applied to the leaflet mesh structures inthe TEE meshes so that the anchor structures match and the complementaryvalve leaflet structures fit the geometry of the reference mesh. Thisdeformation may be described as optimization problem that minimizes anenergy term that is composed of an internal and an external energy part.

After having mutually aligned the first fitted model and the secondfitted model, the first fitted model and the second fitted model maythen both be fused in a step 340 to obtain a fused model. Such fusionmay involve augmenting the first fitted model with a part of the secondfitted model which is missing in the first fitted model, and/oradjusting or replacing a part of the first fitted model based on acorresponding part of the second fitted model having obtained a betterfit. For that purpose, a meshing toolkit may be used to cut and gluemeshes with respect to anatomical labels and application-specificsettings. It is noted that such meshing toolkits are known per se fromthe field of medical image segmentation. In the context of thisembodiment, a result may be a fused TEE/CT model which comprises thehigh-resolution full heart geometry from the reference CT and the valvedynamics from TEE.

Finally, in a step 360, the fused model may be visualized. Suchvisualization may also involve visualizing a discrepancy between thefirst fitted model and the second fitted model in visual relation withthe fused model. Such a discrepancy may be determined in step 350. As aresult, the fused model may be color-coded, e.g., so as to visuallyindicate a remaining local Euclidean distance between both fittedmodels. The fused model may be overlaid over an image, such as a firstmedical image from the first dataset or a second medical image from thesecond dataset. Both medical images may also be fused, with the fusedmodel being overlaid over the fused medical image. In particular, suchimage fusion may be performed based on the fused model. Additionally oralternatively, the displayed image may be processed based on the fusedmodel. For example, the displayed image may be cropped based onanatomical information derived from the fused model. Another example isthat the anatomical structure in the displayed image may be furthersegmented using the fused model. For example, in the context of thisembodiment, the TEE dataset may be cropped to only show the valve motionor the Doppler velocity measurements along with the reference CT.Various other types of processing are equally conceivable.

It is further noted such fusion may involve fusing a dynamic model,i.e., a deformable model which is arranged for modeling a change in theanatomical structure, with a static model. Such fusion is shown in FIGS.5A-5C. Here, FIG. 5A shows an example of a first fitted model 400 in theform of a high-resolution full heart model with a flat annular planededicated to static CT. Here, the fitted model 400 is shown as apoint-cloud of nodes representing a mesh, with a part 402 of the meshbeing rendered using non-translucent surfaces so as to better visualizesaid part. FIG. 5B shows an example of a second fitted model 410 in theform of a medium-resolution heart model with dynamic aortic valve model412 dedicated to 4D TEE. FIG. 5C shows a fused model 420 in the form ofa full heart model with dynamic aortic valve model 422, obtained byfusing the first fitted model and the second fitted model. In such acase, i.e., when one of the deformable models is arranged for modeling achange in the anatomical structure over a series of images, this changemay be visualized in the fused model 420. For example, the fused model420 may be animated or color-coded to visualize the change.

In general, the user may be enabled to interact with the fused model.For example, when visualizing discrepancies between the fitted models inthe fused model, the user may be enabled to apply a local correction tothe fused model, which may be used as feedback in the fitting of thedeformable models as well as in the fusion of the subsequently fittedmodels. The processing subsystem may also be configured for carrying outan action with respect to either of the medical images or either of thefitted models based on the user interacting with a corresponding part ofthe fused model. For example, a landmark set by the user in a medicalimage showing the fused model may be propagated to another medical imageby means of the fused model. Also, an annotation or measurement asgenerated by the user may be visualized in an aligned way across severalmedical images.

It will be appreciated that the present invention may be advantageouslyused in the following other application scenarios:

A volume part showing color-flow Doppler information in TEE may beextracted and overlaid over a static CT mesh;

A segmentation of a TEE volume showing, e.g., only parts of the leftventricle and parts of the left atrium, may be auto-completed by thefull heart anatomy represented in the CT mesh; and

An interventional rotational C-arm CT segmentation showing selectiveparts of the patient's heart contrast enhanced and this giving anaccurate update of the pose of the patient's heart may be auto-completedand accomplished by the anatomy represented in a respectivepre-interventional CT data set.

It will be appreciated that the invention also applies to computerprograms, particularly computer programs on or in a carrier, adapted toput the invention into practice. The program may be in the form of asource code, an object code, a code intermediate source and an objectcode such as in a partially compiled form, or in any other form suitablefor use in the implementation of the method according to the invention.It will also be appreciated that such a program may have many differentarchitectural designs. For example, a program code implementing thefunctionality of the method or system according to the invention may besub-divided into one or more sub-routines. Many different ways ofdistributing the functionality among these sub-routines will be apparentto the skilled person. The sub-routines may be stored together in oneexecutable file to form a self-contained program. Such an executablefile may comprise computer-executable instructions, for example,processor instructions and/or interpreter instructions (e.g. Javainterpreter instructions). Alternatively, one or more or all of thesub-routines may be stored in at least one external library file andlinked with a main program either statically or dynamically, e.g. atrun-time. The main program contains at least one call to at least one ofthe sub-routines. The sub-routines may also comprise function calls toeach other. An embodiment relating to a computer program productcomprises computer-executable instructions corresponding to eachprocessing stage of at least one of the methods set forth herein. Theseinstructions may be sub-divided into sub-routines and/or stored in oneor more files that may be linked statically or dynamically. Anotherembodiment relating to a computer program product comprisescomputer-executable instructions corresponding to each means of at leastone of the systems and/or products set forth herein. These instructionsmay be sub-divided into sub-routines and/or stored in one or more filesthat may be linked statically or dynamically.

The carrier of a computer program may be any entity or device capable ofcarrying the program. For example, the carrier may include a datastorage, such as a ROM, for example, a CD ROM or a semiconductor ROM, ora magnetic recording medium, for example, a hard disk. Furthermore, thecarrier may be a transmissible carrier such as an electric or opticalsignal, which may be conveyed via electric or optical cable or by radioor other means. When the program is embodied in such a signal, thecarrier may be constituted by such a cable or other device or means.Alternatively, the carrier may be an integrated circuit in which theprogram is embedded, the integrated circuit being adapted to perform, orused in the performance of, the relevant method.

It should be noted that the above-mentioned embodiments illustraterather than limit the invention, and that those skilled in the art willbe able to design many alternative embodiments without departing fromthe scope of the appended claims. In the claims, any reference signsplaced between parentheses shall not be construed as limiting the claim.Use of the verb “comprise” and its conjugations does not exclude thepresence of elements or stages other than those stated in a claim. Thearticle “a” or “an” preceding an element does not exclude the presenceof a plurality of such elements. The invention may be implemented bymeans of hardware comprising several distinct elements, and by means ofa suitably programmed computer. In the device claim enumerating severalmeans, several of these means may be embodied by one and the same itemof hardware. The mere fact that certain measures are recited in mutuallydifferent dependent claims does not indicate that a combination of thesemeasures cannot be used to advantage.

1. A system for fitting a deformable model to an anatomical structure ina medical image to obtain a segmentation of the anatomical structure,comprising: an image interface for obtaining a first medical image of apatient and a second medical image of the patient, both medical imagesshowing the anatomical structure and having been acquired by differentmedical imaging modalities or different medical imaging protocols,thereby establishing a different visual representation of the anatomicalstructure in both medical images; a processing subsystem configured for:i) fitting a first deformable model to the anatomical structure in thefirst medical image, thereby obtaining a first fitted model; ii) fittinga second deformable model to the anatomical structure in the secondmedical image, thereby obtaining a second fitted model wherein thesecond deformable model differs from the first deformable model foraccommodating said different visual representation of the anatomicalstructure in both medical images; iii) mutually aligning the firstfitted model and the second fitted model, and iv) after said mutualalignment, fusing the first fitted model and the second fitted model toobtain a fused model, wherein the processing subsystem is configured formutually aligning the first fitted model and the second fitted model by:i) roughly aligning the first fitted model part of and the second fittedmodel, and ii) refining the alignment based on matching of pre-definedanchor structure.
 2. The system according to claim 1, wherein theprocessing subsystem is configured for fusing the first fitted model andthe second fitted model by, augmenting the first fitted model with apart of the second fitted model which is missing in the first fittedmodel; or adjusting or replacing a part of the first fitted model basedon a corresponding part of the second fitted model having obtained abetter fit, further comprising a visualization subsystem for visualizingthe fused model.
 3. The system according to claim 2, wherein thevisualization subsystem is configured for visualizing the fused model byoverlaying the fused model over a displayed image, the displayed imagebeing at least one of the group of: the first medical image, the secondmedical image, and a fused medical image obtained by an image fusion ofthe first medical image and the second medical image.
 4. The systemaccording to claim 3, wherein the visualization subsystem is configuredfor processing the displayed image based on the fused model.
 5. Thesystem according to claim 4, wherein the visualization subsystem isconfigured for processing the displayed image by cropping the displayedimage based on anatomical information derived from the fused model. 6.The system according to claim 2, wherein the processing subsystem isconfigured for determining a discrepancy between the first fitted modeland the second fitted model, wherein the visualization subsystem isconfigured for visualizing the discrepancy in visual relation with thefused model.
 7. The system according to claim 6, wherein thevisualization subsystem is configured for visualizing the discrepancy byvisually coding a display of the fused model.
 8. The system according toclaim 2, wherein the first medical image is constituted by a time-seriesof images, wherein the first deformable model is arranged for modeling achange in the anatomical structure over the time-series of images, andwherein the visualization subsystem is configured for visuallyrepresenting the change in the visualizing of the fused model.
 9. Thesystem according to claim 8, wherein the visualization subsystem isconfigured for animating the fused model to visually represent thechange.
 10. The system according to claim 2, further comprising a userinteraction subsystem for enabling a user to interact with the fusedmodel.
 11. The system according to claim 10, wherein the processingsubsystem is configured for carrying out an action with respect to apart of, one of the group of: the first medical image, the secondmedical image, the first fitted model and the second fitted model, basedon the user interacting with a corresponding part of the fused model.12. Workstation or imaging apparatus comprising the system according toclaim
 1. 13. A method for fitting a deformable model to an anatomicalstructure in a medical image to obtain a segmentation of the anatomicalstructure, comprising: obtaining a first medical image of a patient anda second medical image of the patient, both medical images showing theanatomical structure and having been acquired by different medicalimaging modalities or different medical imaging protocols, therebyestablishing a different visual representation of the anatomicalstructure in both medical images; fitting a first deformable model tothe anatomical structure in the first medical image, thereby obtaining afirst fitted model; fitting a second deformable model to the anatomicalstructure in the second medical image, thereby obtaining a second fittedmodel; wherein the second deformable model differs from the firstdeformable model for accommodating said different visual representationof the anatomical structure in both medical images; mutually aligningthe first fitted model and the second fitted model by i) roughlyaligning the first fitted model and the second fitted model, and ii)refining the alignment based on matching of pre-defined anchorstructure; and fusing the first fitted model and the second fitted modelto obtain a fused model.
 14. A computer program product comprisinginstructions for causing a processor system to perform the methodaccording to claim 13.